Planetary-Scale Wave Structures of the Earth’s Atmosphere Revealed from the COSMIC Observations   总被引：1，自引：0，他引：1       下载免费PDF全文

S. K. A. V. Prasad Rao ANISETTY  P. S. BRAHMANANDAM  G. UMA  A. Narendra BABU  HUANG Ching-Yuang  G. Anil KUMAR  S. Tulasi RAM  WANG Hsiao-Lan  CHU Yen-Hsyang 《Acta Meteorologica Sinica》2014,28(2):281-295

GPS radio occultation（GPS RO） method,an active satellite-to-satellite remote sensing technique,is capable of producing accurate,all-weather,round the clock,global refractive index,density,pressure,and temperature profiles of the troposphere and stratosphere.This study presents planetary-scale equatorially trapped Kelvin waves in temperature profiles retrieved using COSMIC（Constellation Observing System for Meteorology,Ionosphere,and Climate） satellites during 2006-2009 and their interactions with background atmospheric conditions.It is found that the Kelvin waves are not only associated with wave periods of higher than 10 days（slow Kelvin waves） with higher zonal wave numbers（either 1 or 2）,but also possessing downward phase progression,giving evidence that the source regions of them are located at lower altitudes.A thorough verification of outgoing longwave radiation（OLR） reveals that deep convection activity has developed regularly over the Indonesian region,suggesting that the Kelvin waves are driven by the convective activity.The derived Kelvin waves show enhanced（diminished） tendencies during westward（eastward） phase of the quasi-biennial oscillation（QBO） in zonal winds,implying a mutual relation between both of them.The El Nino and Southern Oscillation（ENSO） below 18 km and the QBO features between 18 and 27km in temperature profiles are observed during May 2006-May 2010 with the help of an adaptive data analysis technique known as Hilbert Huang Transform（HHT）.Further,temperature anomalies computed using COSMIC retrieved temperatures are critically evaluated during different phases of ENSO,which has revealed interesting results and are discussed in light of available literature.  相似文献   

伊春东风经营所新元古代花岗质片麻岩U-Pb年代学和地球化学特征   总被引：1，自引：0，他引：1  

王少轶  刘宝山 《世界地质》2014,33(4):780-786

张广才岭中段东风经营所一带发现新元古代花岗质片麻岩,岩石具有高硅、富碱和低钙、镁及偏铝质-过铝质特点,稀土元素配分模式中轻稀土元素富集且缓向右倾斜,重稀土元素曲线较为平坦,为具有铕亏损的海鸥型,富集高场强元素Th、Zr、Hf,亏损Ba、Sr、P、Ti、Nb、Ta等大离子亲石元素,微量元素特征指示其形成于大陆地壳的部分熔融。锆石LA--ICP MS U--Pb定年结果表明,岩石加权平均年龄为(850.2±2.0)Ma,形成于新元古代。构造环境显示研究区花岗质片麻岩形成于挤压造山环境,为造山期的深熔产物。新元古代花岗质片麻岩的发现,表明研究区之前存在一古老的微陆块。  相似文献   

从地震层析速度确定原位岩土力学参数     

金维浚  张衡  尚彦军  段心标  张文辉 《工程地质学报》2014,22(4):765-771

地震纵横波层析成像速度与岩土弹性力学参数有关,多道面波分析（MASW）采用类似二维反射地震处理,得到共中点互相关道集（CMPCC）提取面波频散曲线,由面波频散曲线反演二维速度结构,在岩土结构分层等方面有良好的效果。通过同一剖面的折射地震波层析成像得到纵波速度结构,对岩土层的动弹模量和泊松比等力学参数进行分析,为下一步地质工程设计及岩土力学试验提供参考。  相似文献   

中国地质科学院“大陆构造与动力学国家重点实验室”通过建设期验收     

本刊编辑部 《地球学报》2014,35(3):320-320

正2014年4月8至9日在中国地质科学院院内,由科技部组织的专家对依托中国地质科学院地质研究所建设的"大陆构造与动力学国家重点实验室"组织了验收。验收组首先听取了实验室主任许志琴院士的验收报告,之后对实验室进行实地考察,认为圆满完成了建设期规定的任务,通过验收。"大陆构造与动力学国家重点实验室"获国家科技部批准,2011年10月13日开始为期两年的建设期,并于2013年9月26日在国土资源部科技司的主持下,召开大陆构造与动力学国家重点实验室建设专家预  相似文献   

135~130 Ma: 大别山第二次“去根”时间？   总被引：1，自引：0，他引：1  

崔建军  董树文  马立成  施炜 《地球学报》2014,35(5):553-560

大别杂岩主要由早白垩世侵入岩和三叠纪变质岩组成。它的四周是四条区域性韧性剪切带:郯城—庐江断裂,商城—麻城断裂,襄樊—广济断裂和晓天—磨子潭断裂。其中,晓天—磨子潭断裂和襄樊—广济断裂在早白垩世具有相反的走滑剪切方向:北侧的边界断裂(晓天—磨子潭断裂)是一个左行剪切断裂,而南侧的边界断裂(襄樊—广济断裂)是一个右行剪切断裂。在大别杂岩内部,早白垩世低角度剪切面理的倾伏向以SE向或NW向为主。这些晚期剪切面理上的拉伸线理的倾伏向同样为SE或NW向。大别杂岩总体具有朝SE向挤出和顶部相对朝NW向剪切的构造特征。这些表明晚中生代是该杂岩演化的重要阶段。该杂岩的边界断裂和内部构造特征指示其晚期抬升是沿造山带方向(SE—NW)以低角度方式进行的。这一过程直接导致高压-超高压变质岩和同构造岩浆岩被抬升至近地表。同时,年代学研究表明:大别杂岩(扬子板块东北缘地壳)在晚侏罗世—早白垩世经历大规模混合岩化的时间为145~135 Ma,同造山岩浆作用的时间为145~135 Ma,后造山火山-岩浆活动的时间为135~120 Ma。因此,该杂岩中三叠纪高压-超高压变质岩所记录的早白垩世抬升过程不是印支事件的后续,而是燕山期陆内造山及随后发生的伸展过程有关。尽管这一陆内造山事件的起始时间至今仍不确定,但大别山未变形岩体(130~120 Ma)的年代学研究结果和我们新测得的同构造伟晶岩脉的锆石U-Pb年龄(130 Ma)为早白垩地壳变形提供了良好的上限制约。这样,大别山经历了三叠纪碰撞造山和伸展,晚侏罗世—早白垩世陆内造山-伸展二次过程。  相似文献   

论扬子板块东北缘的俯冲与回撤对山东地块的影响     

王照波  王庆军 《山东地质》2014,(4):13-20

通过对山东中生代侵入岩体的时空展布、岩石化学及同位素特征的综合分析研究,提出了扬子板块东北缘俯冲与回撤的演化机制,分析了在这种机制下的成岩、成矿演化规律。认为扬子板块东北缘的俯冲与回撤控制了山东中生代的地质演化过程,其回撤在岩石圈深部造成的真空,导致软流圈物质的隆升,是胶东金矿大规模成矿作用的内在控制因素。  相似文献   

北山造山带南带构造-岩浆活动与金多金属成矿     

朱江  吕新彪  彭三国  龚银杰 《华南地质与矿产》2014,(1):67-68

<正>中亚造山成矿域是全球最显著的显生宙大陆增生区,该区域大陆增生改造过程中的壳幔相互作用和大规模成矿机理是国内外研究的重要课题。北山造山带地处中亚造山成矿域南缘,是我国西部重要的金、铜、镍、铅锌成矿带。1花岗岩年代学、地球化学特征与动力学背景选取相关中酸性侵入岩体展开系统的锆石U-Pb年代学、岩石地球化学和Sr-Nd-Pb同位素分析,  相似文献   

南秦岭造山型金矿地质特征及成矿模式——以陕西山阳夏家店金(钒)矿床为例     

任涛  王瑞廷  孟德明  樊忠平  李剑斌  王向阳 《西北地质》2014,(1):150-158

在总结山阳夏家店金(钒)矿床产出地质背景、矿床地质特征的基础上,分析和研究了矿区控矿因素、成矿元素基本分布统计规律、成矿流体特征、同位素特征,建立了矿床成矿模式。该矿床金矿体主要受含矿岩系和镇安-板岩镇断裂的次级断裂控制,从地表到深部金的品位、厚度呈波状变化,走向上呈尖灭再现趋势,流体包裹体主要为气液两相,以富CO2(10%)、低盐度(3%~5%)为特征,主成矿期均一温度集中于240~280℃,成矿深度为3km。同位素分析显示成矿流体主要来源于大气水与建造水的混合,部分来源于深部。由此建立了夏家店金矿成矿模式,认为夏家店金矿床以构造-流体成矿作用为主,是由构造的多期作用形成薄弱带,地下热卤水经地热或岩浆驱动在构造薄弱带附近循环萃取矿源层中的矿质在构造带中沉淀而形成的造山型金矿。  相似文献   

How many sutures in the southern Central Asian Orogenic Belt：Insights from East Xinjiang-West Gansu（NW China）？   总被引：1，自引：0，他引：1  

Wenjiao Xiao  ;Chunming Han  ;Wei Liul  ;Bo Wan  ;Ji'en Zhang  ;Song  jian Ao  ;Zhiyong Zhang  ;Dongfang Song  ;Zhonghua Tian  ;Jun Luo 《地学前缘(英文版)》2014,5(4):525-536

How ophiolitic mèlanges can be defined as sutures is controversial with regard to accretionary orogenesis and continental growth.The Chinese Altay,East junggar,Tianshan,and Beishan belts of the southern Central Asian Orogenic Belt（CAOB） in Northwest China,offer a special natural laboratory to resolve this puzzle.In the Chinese Altay,the Erqis unit consists of ophiolitic melanges and coherent assemblages,forming a Paleozoic accretionary complex.At least two ophiolitic melanges（Armantai,and Kelameili） in East Junggar,characterized by imbricated ophiolitic melanges,Nb-enriched basalts,adakitic rocks and volcanic rocks,belong to a Devonian-Carboniferous intra-oceanic island arc with some Paleozoic ophiolites,superimposed by Permian arc volcanism.In the Tianshan,ophiolitic melanges like Kanggurtag,North Tianshan,and South Tianshan occur as part of some Paleozoic accretionary complexes related to amalgamation of arc terranes.In the Beishan there are also several ophiolitic melanges,including the Hongshishan,Xingxingxia-Shibangjing,Hongliuhe-Xichangjing,and Liuyuan ophiolitic units.Most ophiolitic melanges in the study area are characterized by ultramafic,mafic and other components,which are juxtaposed,or even emplaced as lenses and knockers in a matrix of some coherent units.The tectonic settings of various components are different,and some adjacent units in the same melange show contrasting different tectonic settings.The formation ages of these various components are in a wide spectrum,varying from Neoproterozoic to Permian.Therefore we cannot assume that these ophiolitic melanges always form in linear sutures as a result of the closure of specific oceans.Often the ophiolitic components formed either as the substrate of intra-oceanic arcs,or were accreted as lenses or knockers in subduction-accretion complexes.Using published age and paleogeographic constraints,we propose the presence of （1） a major early Paleozoic tectonic boundary that separates the Chinese Altay-East Junggar multiple subduction system  相似文献   

http://www.sciencedirect.com/science/article/pii/S1674987113001606     

Inna Safonova 《地学前缘(英文版)》2014,5(4):537-552

The paper reviews previous and recently obtained geological, stratigraphic and geochronological data on the Russian-Kazakh Altai orogen, which is located in the western Central Asian Orogenic Belt （CAOB）, between the Kazakhstan and Siberian continental blocks. The Russian-Kazakh Altai is a typical Pacific-type orogen, which represents a collage of oceanic, accretionary, fore-arc, island-arc and continental margin terranes of different ages separated by strike-slip faults and thrusts. Evidence for this comes from key indicative rock associations, such as boninite- and turbidite （graywacke）-bearing volcanogenic-sedimentary units, accreted pelagic chert, oceanic islands and plateaus, MORB-OIB-protolith blueschists. The three major tectonic domains of the Russian-Kazakh Altai are： （1） Altai-Mongolian terrane （AMT）; （2） subduction-accretionary （Rudny Altai, Gorny Altai） and collisional （Kalba-Narym） terranes; （3） Kurai, Charysh-Terekta, North-East, Irtysh and Char suture-shear zones （SSZ）. The evolution of this orogen proceeded in five major stages： （i） late Neoproterozoic-early Paleozoic subduction-accretion in the Paleo-Asian Ocean; （ii） Ordovician-Silurian passive margin; （iii） Devonian-Carboniferous active margin and collision of AMT with the Siberian conti- nent; （iv） late Paleozoic closure of the PAO and coeval collisional magmatism; （v） Mesozoic post-collisional deformation and anarogenic magmatism, which created the modern structural collage of the Russian- Kazakh Altai orogen. The major still unsolved problem of Altai geology is origin of the Altai-Mongolian terrane （continental versus active margin）, age of Altai basement, proportion of juvenile and recycled crust and origin of the middle Paleozoic units of the Gorny Altai and Rudny Altai terranes.  相似文献